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The Chemical Context of Life

The Chemical Context of Life. 0. 2. Lecture Presentation by Nicole Tunbridge and Kathleen Fitzpatrick. A Chemical Connection to Biology. Biology is the study of life Living organisms and their environments are subject to basic laws of physics and chemistry

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The Chemical Context of Life

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  1. The Chemical Context of Life 0 2 Lecture Presentation by Nicole Tunbridge and Kathleen Fitzpatrick

  2. A Chemical Connection to Biology • Biology is the study of life • Living organisms and their environments are subject to basic laws of physics and chemistry • One example is the use of formic acid by ants to protect themselves against predators and microbial parasites

  3. Figure 2.1

  4. Figure 2.1a

  5. Concept 2.1: Matter consists of chemical elements in pure form and in combinations called compounds • Organisms are composed of matter • Matter is anything that takes up space and has mass

  6. Elements and Compounds • Matter is made up of elements • An element is a substance that cannot be broken down to other substances by chemical reactions • A compound is a substance consisting of two or more elements in a fixed ratio • A compound has characteristics different from those of its elements

  7. Figure 2.2 Sodium Chlorine Sodium chloride

  8. Figure 2.2a Sodium

  9. Figure 2.2b Chlorine

  10. Figure 2.2c Sodium chloride

  11. The Elements of Life • About 20–25% of the 92 elements are essential to life (essential elements) • Carbon, hydrogen, oxygen, and nitrogen make up 96% of living matter • Most of the remaining 4% consists of calcium, phosphorus, potassium, and sulfur • Trace elements are those required by an organism in only minute quantities

  12. Table 2.1

  13. Case Study: Evolution of Tolerance to Toxic Elements • Some elements can be toxic, for example, arsenic • Some species can become adapted to environments containing toxic elements • For example, some plant communities are adapted to serpentine

  14. Figure 2.3

  15. Figure 2.3a

  16. Figure 2.3b

  17. Figure 2.3c

  18. Concept 2.2: An element’s properties depend on the structure of its atoms • Each element consists of unique atoms • An atom is the smallest unit of matter that still retains the properties of an element

  19. Subatomic Particles • Atoms are composed of subatomic particles • Relevant subatomic particles include • Neutrons (no electrical charge) • Protons (positive charge) • Electrons (negative charge)

  20. Neutrons and protons form the atomic nucleus • Electrons form a cloud around the nucleus • Neutron mass and proton mass are almost identical and are measured in daltons

  21. Figure 2.4 Cloud of negative charge (2 electrons) Electrons Nucleus - - + + + + (a) (b)

  22. Atomic Number and Atomic Mass • Atoms of the various elements differ in number of subatomic particles • An element’s atomic number is the number of protons in its nucleus • An element’s mass number is the sum of protons plus neutrons in the nucleus • Atomic mass, the atom’s total mass, can be approximated by the mass number

  23. Isotopes • All atoms of an element have the same number of protons but may differ in number of neutrons • Isotopes are two atoms of an element that differ in number of neutrons • Radioactive isotopes decay spontaneously, giving off particles and energy

  24. Radioactive Tracers • Radioactive isotopes are often used as diagnostic tools in medicine • Radioactive tracers can be used to track atoms through metabolism • They can also be used in combination with sophisticated imaging instruments

  25. Figure 2.5 Cancerousthroattissue

  26. Radiometric Dating • A “parent” isotope decays into its “daughter” isotope at a fixed rate, expressed as the half-life • In radiometric dating, scientists measure the ratio of different isotopes and calculate how many half-lives have passed since the fossil or rock was formed • Half-life values vary from seconds or days to billions of years

  27. The Energy Levels of Electrons • Energy is the capacity to cause change • Potential energy is the energy that matter has because of its location or structure • The electrons of an atom differ in their amounts of potential energy • An electron’s state of potential energy is called its energy level, or electron shell

  28. Figure 2.6 (a) A ball bouncing down a flightof stairs provides an analogyfor energy levels of electrons. Third shell (highest energylevel in this model) Energyabsorbed Second shell (next highestenergy level) First shell (lowest energylevel) Energylost Atomicnucleus (b)

  29. Electron Distribution and Chemical Properties • The chemical behavior of an atom is determined by the distribution of electrons in electron shells • The periodic table of the elements shows the electron distribution for each element

  30. Figure 2.7 Atomic number Helium 2He 2 Hydrogen 1H He Atomic mass Element symbol 4.003 Firstshell Electrondistributiondiagram Lithium 3Li Beryllium 4Be Boron 5B Carbon 6C Nitrogen 7N Oxygen 8O Fluorine 9F Neon 10Ne Secondshell Sodium 11Na Magnesium 12Mg Aluminum 13Al Silicon 14Si Phosphorus 15P Sulfur 16S Chlorine 17Cl Argon 18Ar Thirdshell

  31. Figure 2.7a Helium 5He 2 Atomic number He 4.003 Element symbol Electrondistributiondiagram Atomic mass

  32. Figure 2.7b Hydrogen 1H Helium 2He Firstshell

  33. Figure 2.7c Lithium 1Li Beryllium 4Be Boron 5B Carbon 6C Secondshell Sodium 11Na Magnesium 12Mg Aluminum 13Al Silicon 13Si Thirdshell

  34. Figure 2.7d Nitrogen 7N Oxygen 8O Fluorine 9F Neon 10Ne Secondshell Phosphorus 15P Sulfur 16S Chlorine 17Cl Argon 18Ar Thirdshell

  35. Valence electrons are those in the outermost shell, or valence shell • The chemical behavior of an atom is mostly determined by the valence electrons • Elements with a full valence shell arechemically inert

  36. Electron Orbitals • An orbital is the three-dimensional space where an electron is found 90% of the time • Each electron shell consists of a specific number of orbitals

  37. Figure 2.8 First shell Second shell y x First shell Neon,with twofilled shells(10 electrons) z Second shell 1s orbital 2s orbital Three 2p orbitals (a) Electron distributiondiagram (b) Separate electron orbitals 1s, 2s, and2p orbitals (c) Superimposed electron orbitals

  38. Figure 2.8a First shell Neon,with twofilled shells(10 electrons) Second shell (a) Electron distributiondiagram

  39. Figure 2.8b First shell Second shell y x z 1s orbital 2s orbital Three 2p orbitals (b) Separate electron orbitals

  40. Figure 2.8c 1s, 2s, and2p orbitals (c) Superimposed electron orbitals

  41. Concept 2.3: The formation and function of molecules depend on chemical bonding between atoms • Atoms with incomplete valence shells can share or transfer valence electrons with certain other atoms • These interactions usually result in atoms staying close together, held by attractions calledchemical bonds

  42. Covalent Bonds • A covalent bond is the sharing of a pair of valence electrons by two atoms • In a covalent bond, the shared electrons count as part of each atom’s valence shell

  43. Figure 2.9-1 Hydrogen atoms (2 H) + +

  44. Figure 2.9-2 Hydrogen atoms (2 H) + + + +

  45. Figure 2.9-3 Hydrogen atoms (2 H) + + + + + + Hydrogenmolecule (H2)

  46. A molecule consists of two or more atoms held together by covalent bonds • A single covalent bond, or single bond, is the sharing of one pair of valence electrons • A double covalent bond, or double bond, is the sharing of two pairs of valence electrons

  47. The notation used to represent atoms and bonding is called a structural formula • For example, H—H • This can be abbreviated further with a molecular formula • For example, H2

  48. Figure 2.10 Name andMolecularFormula Electron Distribution Diagram Lewis Dot Structure and Structural Formula Space- Filling Model (a) Hydrogen (H2) H H (b) Oxygen (O2) O O (c) Water (H2O) H O H (d) Methane (CH4) H H C H H

  49. Figure 2.10a Name andMolecularFormula Electron Distribution Diagram Lewis Dot Structure and Structural Formula Space- Filling Model (a) Hydrogen (H2) H H

  50. Figure 2.10b Name andMolecularFormula Electron Distribution Diagram Lewis Dot Structure and Structural Formula Space- Filling Model (b) Oxygen (O2) O O

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